MIC2196 Datasheet, PDF(7/11 Page) Micrel Semiconductor

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MIC2196 Datasheet, PDF (7/11 Pages) Micrel Semiconductor – 400kHz SO-8 Boost Control IC

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MIC2196

The description of the MIC2196 controller is broken down into

several functions:

â¢ Control Loop

â¢ PWM Operation

â¢ Current Limit

â¢ MOSFET gate drive

â¢ Reference, enable & UVLO

â¢ Oscillator

Control Loop

The MIC2196 operates in PWM (pulse-width modulated)

mode.

PWM Operation

Figure 2 shows typical waveforms for PWM mode of opera-

tion. The gate drive signal turns on the external MOSFET

which allows the inductor current to ramp up. When the

MOSFET turns off, the inductor forces the MOSFET drain

voltage to rise until the boost diode turns on and the voltage

is clamped at approximately the output voltage.

Conditions:

VIN = 3V

VO = 9V

IO = 0.6A

PWM Mode Waveforms

Inductor Current @

1A/div

MOSFET gate

drive @ 10V/div

Switch Mode Voltage

(MOSFET Drain)

@10V/div

VOUT Ripple Voltage

@50mV/div

TIME (1Âµs/div)

Figure 2. PWM Mode Waveforms

The MIC2196 uses current mode control to improve output

regulation and simplify compensation of the control loop.

Current mode control senses both the output voltage (outer

loop) and the inductor current (inner loop). It uses the inductor

current and output voltage to determine the duty cycle (D) of

the buck converter. Sampling the inductor current effectively

removes the inductor from the control loop, which simplifies

compensation. A simplified current mode control diagram is

shown in Figure 3.

I_inductor

VIN

Micrel

I_inductor

Gate Driver

I_inductor

VCOMP

Voltage

Divider

VREF

Gate Drive at OUTN

TON

TPER

Figure 3: PWM Control Loop

A block diagram of the MIC2196 PWM current mode control

loop is shown in Figure 1. The inductor current is sensed by

measuring the voltage across a resistor, RSENSE. The current

sense amplifier buffers and amplifies this signal. A ramp is

added to this signal to provide slope compensation, which is

required in current mode control to prevent unstable opera-

tion at duty cycles greater than 50%.

A transconductance amplifier is used as an error amplifier,

which compares an attenuated output voltage with a refer-

ence voltage. The output of the error amplifier is compared to

the current sense waveform in the PWM block. When the

current signal rises above the error voltage, the comparator

turns off the low-side drive. The error signal is brought out to

the COMP pin (pin 1) to provide access to the output of the

error amplifier. This allows the use of external components to

stabilize the voltage loop.

Current Sensing and Overcurrent Protection

The inductor current is sensed during the switch on time by

a current sense resistor located between the source of the

MOSFET and ground (RSENSE in Figure 1). Exceeding the

current limit threshold will immediately terminate the gate

drive of the N-channel MOSFET, Q1. This forces the Q1 to

operate at a reduced duty cycle, which lowers the output

voltage. In a boost converter, the overcurrent limit will not

protect the power supply or load during a severe

overcurrent condition or short circuit condition. If the

output is short-circuited to ground, current will flow from the

input, through the inductor and output diode to ground. Only

the impedance of the source and components limits the

current.

August 2004

MIC2196

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